Glass-pressing machine.



- K. E. PEiLE'R. y

GLASS PRESSING MACHINE., L

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GLASS Pnfssmc MACHINE. -1 APFucA-nou m'ED 1116.11, 1913.

I3 SHEETS-SHEET 2.

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K. E. PEILER.

GLASS PRESSING MACHINE.

13 SHEETS-SHEET 3.

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GLASS PRESSING MACHINE'. APPLICATIQH rlLlEn vAUG; 1|. ma.

I3 SHEfTS-SHAET 4.

mmm Jan.. 21, 19m;

K. E. PEiLEn. l 'GLASS PRESSING MACHINE.

' APPLICATION FILED AUGJI. |913.

Pawmd Jim.y 214, uns.

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K. E. PEILER'.

GLASS FHESSING MACHINE.

K. E. PEILER.

GLASS PRESSINGMACHINE.

APPLICATION man Auml. 1913.

lgz. 'Patented Jun. 21,1919.

13 SHEETSSHEEl 7.

K. VE. PEILIR.l l GLASS PREssIIIG MACHINE. Y APPLICATION FILED AuG.II. I9I3. 11,292,33.

. I3 SHEETS- snm a.

Patented' Jan. 21,1919.

` K. E. PElLEB.

GLASS PREssmcy MACHINE. APPLICTION FILED AUG.H. l9l3.

'Patented Jan. 21.1919] i 13 sHEETssHEE1 9.

K. E. Prima. GLASS PRESSING MACHINE? APPLlCATION FILED AUG.ll. i913.

d 22 mm way K'. E. PEILER. GLASS 'MESSING MACHINE.

APPLICATION FILED AUG.II, IQIH.

Patented, Jfm. 21, 1919. I3' SHEETSTSH'EET II.

K. E. PEELER.

- GLASS Pmssm mamme.

` APPLICATION FILED AUGJI, 12H3Y n 1 v .1,292,33... :.uien'tfed Jan. 21,1919,

13 SHEETS--SHEEY l2.

K. E. PEILERL GLASS PRESSING MACHINE.. APPLICATION man Aue. r1. 191s.

Wzexes:

KARL E. PEILER, OF HARTFGLRD, CONNECTICUT,

ASSIGNOR TO HARTFORD-FAIRMONT- COI'PAE'Y, OF CANAJOHARE, NE'vV YORK, A CORPORATION OF vlll'll'ulll YORK.

GCLSS-PRESSIN G IVIACHIN'E.

raeaeas.

Application filed August 11, 1913.

` To all 'wim/n t may concern:

Be it known that l, KARL E. Pinnen, a citizen of the' United States, residing at Hartford, in the county of Hartford and State of Connecticut, have invented new and u. eful Improvements in Glasslressing Machines, of which the following is a spcciica tion. Y

This invention is an organized and improved machine for shaping molten glass by pressure, the object of the invention being to provide a well organized, rapid, eilicient, and substantially automatic machine, with adequate provision for safety of the machine, and for applying the required amount of pressure to the glass and discontinuing that pressure without overstraining or damaging either thepressed ware or the ma chine.

2U Among the difficulties incident tothe rapid and automatic pressing of glassware, which are overcome by this machine, may be mentioned the difficulty of providing and feeding to such machines a suitably regulated supply ofvmolten glass in separated masses or gathers of proper volume, of uniform size and plasticity, and 'fed to the press in lregular succession.- It thc-gather"is .too small, it does not fill up the available space between the mold and plunger. If' too large it overlills this space and is liable to strain the mold, the pressing mechanism, and the glassware itself, so that the latter will present a cracked or crizzled appearance. If the gathers of glass are too hot and plastic, they are liable to overheat the mold and plunger and require to be held in place longer while becoming set. if too cool and viscous they require greatly increased pressure to fill up the mold, besides being liable to overstrain and disarrange or break the machine.

Another important object oi this invention iste provide in such a highly organized and rapid working machine a proper correlation and cerdination ot' the parts most directly exposed to the heat or' the glass, taking into account the proportions of the parts to each other in number and relativo size, and p/roviding not only the mechanism for working the several parts in suitable time and otherwise in proper relation to each other, but alsoproviding suflicient working space and clearance for the Specification of Letters Patent.

Patented Jan. 2l, 1919.

serial no. :fs-1,194.

proper operation of the various mechanisms. For example, it is desirable to kes the lower portions of the plunger' and mol relatively cool, since they remain longest in direct con` tact with the hottest portion of each succes-4 sive gather of glass.' At'the same timev 60 it is desirable to keep the mold ring and the upper portions of the plunger and the mold relatively hot, since they remain for a shorter time in contact with the thinner and cooler edges of the glass gather, which are. extruded toward the top edges of the mold by the pressure below; and their function is to shape this cooler edgel portion without too greatly reducing the heat and plasticity of these edges by their own absorption of the heat from the glass during its flow toward the top.

The machine herein illustrated is provided with a plurality of pressing or shaping mechanisms cach of which has a pressing plunger. a mold ring and a pair of molds, with appropriate mechanism ior operating 'these parts. This arrangement allows suflicient time for the ware pressed in each mold to remain therein long enough to become properly cooled and set in that mold, while another piece of ware is being pressed in another mold; and also :facilitates the maintenance of proper operating lternperature in the mold, mold rings and plungers. 86 The plunger of each of these mechanisms operates in conjunction with a single mold ring alternately uponthe two different molds of that mechanism. The number of pressing mechanisms employed, and the 90 relative number of molds, mold rings and plungers employed in each mechanism should be adapted to the requirements of each case, according to the size and character of the ware, the rapidity oi the der sired operations and other conditions which will be understood by those familiar with the art of glass making.

Figure 1 of the drawings is a side elevation, 'in section taken through the vertical center and axis of revolution oi" the machine. Fig. 2 is a plan view, some portions being broken away to show the diilerent mechanisms. Figa 3 is a front elevation of the main driving mechanisn'i, in section taken substantially on the line 3 3 oi Fig. Q. Fig'. 4 is an elevation showing the upper portion of the machine in section taken sub- -slanaauy neng ai@ una i-fi. of ing.

Fig. is a `plan view of the central portion of the machine, substantially at the plane indicated by line of Fig. 1. Fig. 6 is' aside eleva-tion in enlarged scale of the mold and plunger operating mechanism, in section taken on the line 6-6 ofvFig. 7.

Fig. 7 is a front view' projected from the left hand side of Fig. 6, some portions of the mechanism being shown in section taken. through its longitudinal center. Fig.` 8 .is a plan view of a part of the machine-in sec tion taken on the line'8-8 of Fig. '7. Fig. 9 is a similar'partial plan view in section taken ou the line )--9 of' Fig. 7 Fig. 10 is also .a fragmentary plan view in section taken on the line 10-10 of Fig. 7. Figs.

11, 12 and 13 are sectional side views, showing the constructiomand illustrating the op eration of' the mold carrying and reversing' mechanism. Fig. 11 shows the reversely disposed molds with the right hand. mold in pressing position and the left hand mold in' discharging position. Fig. 12v shows the mold reversing sector and pawl in the ree.

trac-ted portionlofits mold reversing inovement. F ig. 13 shows the mold supporting gate retracted and the mold carrier in partly reversed position. Fig. 14 is a plan view andv Fig. 15 a side elevation of a pair ofv molds and their carrier, showing the ware retaining fingers and their operating means. Fig. 16 is a front elevation showing the mold ring operating yoke andits connections.

i Fig. 17 is an elevation in section taken through its longitudinal center of .the pressing head and showing its magnetic releasing` connection. Fig. 18 is an elevation show ing a pair of the molds and their tapping mechanism 'for loosening the ware. Fig. 19

Vis a chart' or diagram for illustrating the relation of the parts and the various positions occupied by themin operation.

Figs. 2() to 27 inclusive are side views in smaller scale, and somewhat of a diagram-- matic character illustrating the positions of the principal parts' ofthe pressing mechani-sm at different phases or stages in their operation, Figs. 20 to 25 inclusive illustrau y r center. These revolving parts are support-l ed upon a table 3, which-is fitted to .revolve hereby-around the lower portion of the column 2. ball bearings Al being` preferablv employed to reduce the friction. The circumferential edge of the table is provided with gear teeth 5, which mesh with a..pinion 6 on the upper end of a vertical driving shaft 7,

which is mounted to revolvev in a 'bracketS secured to the base 1. A worin gear 9 fixedl to the. lower end ofthe shaft 7 is 4driven by a worm 10 on the horizontal driving shaft 11, supported in the brackets-12 and driven by means of a belt from anyconvenient source engaging with the'A pulley 13. Or' an electric motor may, if preferred, be mounted on an extension of the base 1 for driving the shaft 11. This driving train rotates the table 3, carrying'l a plurality of pressing mechanisms which revolve with the table around the central coluinn2. I

This driving mechanismfis also f ad apted to drive a pressing head 15 common to all the pressing mechanisms, having a driving connection extending axially through the column 2, consisting-of a driving rod 16,

` connected by a link' 17 with the end of the working beam 18, which is pivoted at 19 on the bracket 20.. The outer end 'of the work L ing beam is provided with a cani' pin or 'roller 22, engaging with the peripheral surface ofthe cam 23, which is mounted onthe 25 supported on the base 1. One end-of this horizontal shaftQLl journaled in the bracketsv shaft Vhas fixed upon itaworrn wheel'26 which meshes with the worin on the IdriV-. ingshaft 11;. Thus this driving -mechanism operates to rotate the table 3A and move-the driving rod 16 y,up and down in predeter# mined and regular relation to each other.'

The driving rod 15 is detachably connected to the pressing head 15 by means of an eledtroinagnet, as will be described later.

The machine illustrated herein being providedv with six pressing mechanisms, the pressing head iis moved up .and down six times for each rotation of the table. Obviously, however, this proportion should be adapted to the number of pressing mechanisnis employed.

f The shaping or pressing molds and their inold `riiigs and the shaping or pressing plungers are supported upon the table 3 for revolution around the 4central column 2, and

their free workingmovementsl are imparted by engagement with; stationary eaJms also disposed in concentric -relation-tothe column. lhe peripheral cam 30 forI operating the mold rings is here shown tobe supported p l directlv upon the base 1, ywhilethe cam paths or grooves for operating the plunger and mold'mechanisms are made in another cam- 31, which is hereinshown to be an integral piece supported andfixed upn the outside ofthe column 2 insideof theA turret 61.

'The base of the turret 61 rests upon and is firmly secured to the table 3, and revolves therewith; Toward the upper .end ofthe turret its central portion is jjournaled at 6a to the upper end of the column, thus centering these two parts with each-'other and miiiso 1,209,033 p p m tually sustaining each other. The turret is generally circular in form, inclosing within it the cam 31. The body or Wall of the turret forms a support for some of the sliding chine for cooling the shaping instrumentalities or for other purposes,'the vacuum, or the air or fluid'supply being induced or introduced to these chambers as shown in Fig. 4, and as hereinafter more fully described. This revolving structure, mainly comprising the table, the annular walled or tubular -turret secured thereto, the vertical guides rigidly supported'at top and bottom, all turning as a unitary structure around the central column, forms an extremely rigid structure well adapted to withstand the severe and intermittent torsional and other rcsistanc'es encountered in revolving these parts continuously, and at the speed required for their greatest efficiency. /The practically continuous annular wall of the turret, in addition to thus stiifening the entire rotating structure, is utilized to form' guideways for the connections between the outside working parts and the inner cams and pressing head, which operate those exterior parts, besides serving to inclose and protect the operating parts referred to, from shreds or slivers of glass and other flying or floating foreign substances which might injure the mechanism, and also from the heat of the shaping mechanisms, attendant upon their shaping operations.

The molds are carried upon a series of trunnioned carriers 41 resting on the top of the table 3, while the mold rings and plungers are mounted on yokes which are fitted to slide 'vertically on guide rods 32, supported by the table 3 and turret G1 and preferably arranged in pairs spaced at equal angular intervals around the table. The mold rings 105 are raised and lowered from below by means of the cam 30, while' the plungers are raised and lowered, through their free, or non-pressing movements by means of toggle joint connection from the rock shaft 33, actuated through a rack 34 from the cam groove 35 in the cam 31. For

its shaping pressure on the glassware, each plunger is also actuated by an independ' ently operated auxiliary or coacting press- `ing device, through the pressing levers 36,

which 'ire mounted for rocking.movement concentrically with the shafts 33, their outer ends conditionally engaging with the toggle joint, when the latter normally reaches its pressing position, by means of pawl's 37, as shown in Figs. 1, 20 and 21. These pressing levers 36 are disposed around the machine preferably in substantially radial relation to the center of revolution, their inner ends being operated by the centrally disposed pressing head 15 through the medium of the releasingr connection above referred to, which may be adjusted or regulated to release at the pressures required or desired for f lifferent articles.

The members of the machine which are involved in the application and transmission of the principal pressures arc so disposed as to act and react at or substantially parallel with the axis of revolution of the press, with a minimum of stress acting in a direction transverse to that axis. The principal final pressure is transmitted in a vertical direction to and'through the pressing head l5 at the center of revolution of the plungers. The resultant pressure upon the plungers is in a downward direction, while the reacting pressure upon the rocker shaft 33 is in an upward direction. Thus the stresses are disposed not only in an up-and-down direction parallel with the vertical axis of revo lution of the machine, but are balanced in opposite directions as far as possible, upon the revolving unitary' structure of the tur ret and its appurtenances. The pressure is transmitted to the revolving levers not only at the center of their revolution, but in an axial direction, which in connection with the ball bearing mounting of the swiveling pressing head enables the required pressures to be transmitted smoothly, with a minimum of friction, and of disturbance to the balanceof the entirel revolving structure.

Following this brief general description of the main part-s, they will now be des' scribed in detail The molds 40, which may be of any desired ferm, are arranged in pairs upon o i posite lateral wings 4:4 of a trunnioned mold carrier al, having a cross-sectional outline somewhat resembling the letter Z, as best shown in Figs, l, 11, 12 and 13. For con vcnience in changing these molds they are preferably made separate, and are centered and clamped in proper position on their carriers in any convenient way as by means of the rings 42. The molds are herein shown to be provided with bottom valves 43, the ends of which project through the supporting wings'tf of their mold carriers, to facilitate loosening and delivering the ware from the molds when the latter are inverted.

The centers of the two molds of each pair are disposed at equal distances from and on opposite sides of the axis of the mold carricr. The oppositely disposed trunnions 45 and 46 of these carriers are mounted -for turning movement in 4brzu-lwts 47 and -4-8, secured upon the table 3. This trunnioncd 'sie ' turned through half revolution between the successive pressing operations, thus inverting the mold containing the ware last pressed, and bringing the einer now empty mold into pressing position right side' up and in line with its plunger and mold ring. This reversing operation is accomplished by the mechanism shown in Figs. 6, 7 and 8,

and 11 to 13. ratchet wheel 51 is fined upon one of the trunnions, or an extension 52 thereof, as best shown in Fig. An annular flange of this ratchet is provided on its inner surface with two oppositely disposed notches 53 for receiving the end Aof a pawl 54, which is mounted on a sector gear 55 fitted to turn freely on and concentric with the trunnion bearing. This pinion is turnedl back and forth slightly moreAthan half a revolution by means of a sector gear 56 mounted on a stud 57 carried by the lug 58. That sector is provided with gear teeth 59 lengaging with the teeth of a racl 60, which is fitted for vertical sliding movement in the turret 61, as -bestshoivn in Figsmi, 6 and 8. The, rack is provided with a 'ram pin or roll 62 engaging with the cam groove the point Where it is desirable to bring 63 in the peripheral surface of the fixed cam 31, that cam path being so disposed and shaped as to turn the mold carrier half a revolution'in tlie di1ertion of the arrow show-n in Fig. 13, *asjeach pair of molds reaches in its revolution around the column an. empty mold into its pressing position.

In order to enable the molds thus to reversed, the table 3 is recessed at 65 i clear the revolving portions of the mold carriers and their molds; `and in order to provide a suitably firm support for the molds during the pressingA operations, a movable abutment, which in this case is in the form of aslide 66, best shown in Figs. 11, 12 and 13, is employed, provided with a cam roll 67 engaging with a cam surface 68 on the cam 31, which draws back the slide 66 againstthe pressure of springs 71 to the position shown in Fig. 13 just before the inoldsare reversed; then lets the slide forn ward'avai to the osition shown in Fi s.

2:, l, P g

' 11 and 12 to form a solid base beneath the ing I p'ressure.

mold for supporting it againstthe shapshow'n as being intwo parts, 69 and 70, de-

' tachably fastened together by screws.

` te the mold carrier at a point which permits xii the finger to swing over and away from the incid opening, as shown by comparison. of

y For convenience in assembling and disassembling, the slide` is herein mold carriers.

neeaoae vthe mold, an extension 77 of the finger coln lides with a cam-like projection` 78 attached to a fixed portion 79 of the machine, there-by swinging the retaining finger ov r the mold opening, and thus preventing the ware from dropping out during and after inversion of the mold, until the ware arrives over the take-ofi1 device or other intended delivery position, whereupon the outer end SO of the finger collides with another cam-shaped projection 81, whereupon the retainin finger 73 is swung backwardly from in ront ofv the ware, allowing the latter to drop out. In the particular arrangement here shown, in order to allow the finger to pass by the cam projection 8 1, the latter is hinged at 82, and held in its operating position by means of a spring 83 against a stop pin 84. After the retaining finger 73 is swung to its fully opened position., its continued movement swings the cam projection 81 against the pressure of the spring untillthe finger passes by, whereuponthey cam projection returns-to its first position. t

Suitable means are provided for holding the retaining lingers in their open and closed positions. The means here shown consist ofl a spring 87 coiled around a guide or' plun-- ger 88 fitted to slide in the stud 89 and joined at 90 to an -arm of the retainin finger 73. The pressure of the .spring 8' tends to hold the retaining finger in either of its two positions, against the stop pins 91.

In order to insure the discharge of the pressed ware from the mold, a tapping detached to the frame or baseof the machine. j

These hammers are provided with rear* ward extensions 99 which project beneath the cross pieceplOO of the brackets and thus serve as stops for the lower position of the.v

hammers. For lifting and dropping the hammers, they are provided with shoulders or projections which engage with inclined ledges 101 formed on the outer ends of thel As these carriages swing past the hammers the shoulders 102 of the i latter ride upon these inclines, thus raising the hammers which then' successively fall into a depression of the ledge 101, as the center of the mold valve passes under the successive hammers. The succession of blows operates to loosen the ware from the mold. A. greater or less number of the hammers may be used according to the nenesl lcured to each of the yokes 10G, concentricaliy with the mold ring, as shown in section in Figs. 7 and 10. These mold ring yokes are moved up and down on the guide rods 32, by means of the cani 30 (Figs. 1 and 2) engaging with a cam pin or ioll 108 on a yoke 109 secured at its ends to connecting rods 110, which extend upwardly through the guide rods 32 which are made in tubular form for this purpose. The lower portions of these connecting rods till the bore of the tubular guide rods, but higher up they are turned to a smaller' diameter to receive the sleeves 111, which also lit the interior bore of the guide rods. The sleeves 111 are held downwardly against the shoulders 112 ofthe connecting rods, by means of the springs113, the upper ends of which abut against adjustable collars 11/1 fitting in the upper ends of the tubular guide rods The collars are adjusted by means of the nuts 115 to vary the tension of the spring pressure upon the yokes 106. Connection between the mold ring yoke 106 and the connecting rods 110 is made by clamped to the yoke by means of the hook bolts 119, or in any other convenient way.

The plungers 121 tor shaping the interior contour of the glassware are mounted for vertical movement into and out of the molds and mold rings. They are attached to the plunger yokes 122 (Figs. 1, 6, 7 and 9) which are Iitted for sliding movement upon the guide rods 32 above the respective mold ring yokes 10G. rlhese yokes, carrying the plungers, are moved up and dowii upon the guide rods from the lowest position shown in Fig. 1 to the highest position shown approximately in Figs. 6 and 7 by means of a stationary cam 31, around which the plungers are carried by the rotation of the machine. The upper and lower cam surfaces 123 and 124 of the cam engage with a cam pin or roller 125 appurtenant to a rack 34, which is fitted for sliding movement in and revolves with the turret 61 carried by the table. The upper end ot the rack 34 is provided with gear teeth engaging with a sector gear 126 turning upon the shaft which is supported at .its ends in the bracket 127. These brackets are clamped upon the upper end of the turret and extend outwardly to the upper ends of the guide rods 32, which they thus serve so support in iixed parallel relation to each einer. The sector gear 126 is provided with a crank arm 128, to which is pivotally altached a connecting rod 129 having its lo -er bifur- -cated ends pivotally attached to thplunger means ot' clutch dogs 117, which are secured at the backs of the yokes and project through slots 118 in the tubular guides 32 and have notched interlocking engagement with the wall of the sleeve 111, as bestshown in Figs. 6 and 7.

As each mold revolves into its pressing position, the vmold ring is moved down and seated on the mold by means ot' the cani 30, which is shaped so as to carry the yoke below the level actually needed for bringing the mold ring into contact with the mold, the springs 113 yielding to the saine extent, thus putting tlie pressure ot those springs` upon the mold rings to holdvthem in position.` In case the downward movement of the mold ring should be obstructed by accident` suoli as the breaking or disarrangement of the parts below it, the springs 113 enable. the mold ring to yield to the obstruction, while permitting the cam yoke 109 to n'iake its complete stroke without undue strain.

lhe mold rings 105 are preferably made sepaial'ilo troni thc yoke in-order that they may easily he removed and replaced when worn out.- or to enable different mold rings to be employed. The mold rings are yoke 122 by means of the wrist pins 130, the endsv ot which are secured to the yoke 122 by means of caps 131 (Figs. 7 an 9). The arm 128 and the connecting rod 29 serve as. a toggle joint, which at their lo` 'er position shown in Fig. 1 facilitates the application ol the pressing pressure upon the ware, as hereafter explained. To enable the lowermost position ot the yoke to be adjusted to regulate the thickness of the ware, the upper end of the connecting rod 129 is mounted upon an eccentric sleeve 132 supported by the wrist pin 133. For convenience in as- 4 sembling and adjusting the parts, the connecting rod 129 is herein shown to be made in `two longitudinally separable parts 134 and 135 (Fig. 7). tlufuppcr ends ot which are slipped toward each other upon opposite ends of the eccentric bushing 132, and secured together hy bolts 1,36, leaving a central flange otl that bushingl exposed tor convenient rotaryadjustment oir its eccentric portions, by means of the spanner holes 137 or in au other convenient way. The bushing is clamped or otherwise secured in `its adjusted positions by means ot screws 138 bearing against the wrist. pin 133 (Fig. 0)

when the desired reach is obtained.

"ihc plungers 121 are seated in the yoltes 22 concentiia'ally with the respective, molds l l0 and mold rings 105i with which tiieycce cam roller all the way around the cam, butare relieved at and adjacent to the pressing position as shown in Figs. 22 and 23. The

clearance between `the roll and lower cam surface 124 is toprovide for thecpossihilitythat the normal downward movement of the plunger may sometimes be obstructed either y misdelivery of a charge of glass or by some disarrangement of the parts. Therefore the plunger is not moved positively I' downward, but is let down upon the glass by the upper cam surface 123 as shown in lFig. '21., being impelled by 4its own'gravity, due to the. weight of the plunger, yoke and other -attached parts aided or counterbalanced as may be needed by weights or springs.

contour ofthe upper cam surface 123, which is also relieved, as shown in Figs. 22, '23 at A and near the pressing position, so as to clear the roller, andy allow the plunger. to be moved further by the pressing mechanism to be hereinafter described. Y

In order to relieve the glassware from undue pressurevof the weight of. the plunger and yoke, after' the shaping pressure has been applied and discontinued, an adjustable counterbalancing device is employed at someportion of the plunger mechanism.` lt is herein shown as being applied at the 'top of the rack ,34C (Figs. land G). A. buer or plunger 141 pressed down by the spring 144 is mounted for vertical sliding movement in the bracket 14,2, with its lower end project-v ing into the pathway yof' the tappet 143 ap purtenant to the rack 34. The tappet or the plunger, or a bracket carrying the plunger, may be made vertically ustable for convenv, ience in setting and adjusting the device.' A tension screw 145 or any other well-known I 'or convenient means is employed sto enable the countei'balancing .torce of the springto be adapted to the relative weights ofithe parts which require to be counterbalanced.

.l The pressing mechanism for applying a denite and closely adjustable amount of shaping pressure to the plungers upon the glassware, acts through and coacts with the plunger mechanism, but is (,)therwise mountedl and operated independaintljr ot' that plunger mechanism. anism is arranged to act upon the plungers in succession, conditionally upon the normal operation of the latter, as they approach the pressing position shown in Fig. 21. The pressing movement .is imparted by the cam 23 through the working beam 18 acting upon the driving rod 16 which extends vertically This downward movement of the" plunger and yoke is thus regulated by the This pressing mochev through-the column 2 at the center ci revolution ott the involving` plunger mechanisms. To the, upper end oi' the rod is secured an electro-magnet la? by' means of a flanged sleeve 1419 which is fitted for sliding movement in the central upper portion of the framing (Figs. 1 and The latter pfreiierably provided with a bushing 148' which serves as a bearing tor the sliding sleeve 149 of the magnet, and also serves as abearing for an air inlet 150, as is her-einfafter more fully described. `When in action, the lower surface of the magnet 14:7 engage with an armature 151, secured to the friction collar 152 forming -one memberoi" a hall bearing containing the balls 153, which enables the armature to Stand still when seized by the magnet, whilevallowing the other members 154 and 1550i the friction bearing to turn with the revolving pressing head 15, to which they are secured. The friction ring 155 made separately for convenience or as sembling Vand adjustment is secured to the revolving casing 154, the latter being .madeto revolve by its connection with the pressing head best slioivn in Figs. t and 17.,

,casing 154 is' provided withprojeeting hubs 162 whichlserve as guides, engaging with `and sliding upon the guide rods 15G, the lower e'i'ids of which are secured inthe upper por-` tion of the revolving turret 6l, while the upper portions are supported in the cap or crown 157 of the revolving parts. These guide rods are also utilized asj supports for a spring device tor increasingthe gap The upper endsof the guide rodsl are provided i ith shoulders 158 uponvwhich are 4seated 'the thimbles 159 and 1GOl facing each between the magnet and its armature a't- 'pressure releasing operation hereinafter deuit' other and having a spring ll'between them tendingto press the thimbles apart. The bossefsr16`2 of the casing 154: when carried upward by the magnet collide with the lower surfaces ot' the. thimbles 160 and h' cow ti'i'iuedmovement receive the increasing pressureot the springs 161. rlhese springs are `not strong enough to overcome the :force of the magnet, which in ne normal working of the n iachine is intended to be overcome by the increased resistance of the i-lass when it has completely filled the mold and mold 'ning'. But when thus overcome and sep aaterl bythe resistance of the glass, the gap between the magnet and its armature is quickly increased by the tension of fthe springs 161. If, however, the mold should be empty, through failure to receive a charge ot' glass, or while starting up the machine, or otherwise, 'the magnet and its armature will be forcibly separated by thev meetingl of the ends of the thimliles 159 and 1GO, which thus oppose a solid resistance the pressing head.

to thefurther upward movement of the armature, thus forcibly separating it from the magnet and thereby preventing the bottom ends of the plungen. from abutting against and perhaps injuring the plungers or the bottom valves of the mold. A further important purpose served by this positive separation of the magnet and armature is that the pressing levers are thereby enabled -to make their full Stroke at each successive pressing operation, whether operating no1'- mally upon the glass, or acting upon empty molds. The leads ot' the magnet windings may be, run through holes or grooves to the top ot the driving rod 16 as shown in Fig. 17, and thence to any suitable energizing means.

The operating connect-ion between the centrally disposed pressing head and the outlying revolving plunger mechanisms .is e'- fected by means of a pressing lever B6 for ach of those mechanisms, as best shown in Figs. 1, Q and 5. The inner ends of these levers are rounded and seated in blocks 164 fitted for radial sliding movement in the centrally disposed pressing head 15, which revolves withy the plunger mechanisr convenience of construct-ion and assembling the pressing head is preferablyv made of separable parts.` The easing 151. and the tlange 165 of the sleeve 166 are joined together by means of triangular spacing blocks 167 (Fig. 5) secured by means of screws 168 and also preferably tongued and grooved or doweled to locate and maintain them in proper position. These triangular sepa `ating blocks 1(3 7 form between them seats for the sliding boxes 164 allowing tor radial sliding move- -ment of the block suiiicient to allow it to freely follow the are oi swinging movement of the press levers 36. The sleeve 166 is fitted for sliding movement in the column 2 and may also serve as a guide for the middle portion of the magnet driving rod 16. The lange 165 ot' the sleeve is here shown as tittingl inside oi an upward annular extension 1(39 ot' the nut 170 which thus serves as a pneumatic dash pot. for cushioning the fall ot' the pressing head 15 and its connected parts when the armature is released from the magnet.

The pressing levers 3G are herein shown to be disposed in generally radial relationto The v are of open term (Fig. 2). the opposite sides of which are supported upon the rock shaft 33 (Figs. 1 and 2l hereinheiore described. Thus the. swinging movement of each pressing lever 3G is concentric with the oscillating movementof the crank 128 which operates the associated plunger. The press levers are provided with coupling devices which under normal conditions of working operate upon the crank 128 and its attached connecting rod 129 as shown in,Fig. f1, acting to For members and thereby imparting the shaping vpressure to the glassware. lawls 3T are mounted to swing upon pivot pins 172 at or near the outer ends ol the pressing levers -t in engaging relation to the outer surfaces ot' the respective cranks 12S. against which the lower ends ot the pawls are liiressed by means oi springs' 3S. Stops 176 on the pawls engage with stops 17| on the pressing leversto limit the inward movement of the pawls.

The plunger mechanisms driven by the cam 23 operate once during each revolution ot' the table. while the pressing Tam 31 operates the pressing mechanism a number ot' times during each revolution of the table equal to the number oi' plunger mechanisms, which in thc six plunger machine illustrated herein would he six times. The principal movements and relative positions ot the plunger and pressing mechaiiisms are illustrated in the diagrammatic views of' Figs. 19 to Q5 inclusive. The plan view, Fig. 19, shows the sifv plungers 121 and the radial lines 1` and 2O to 25 inclusive indicate those rotary positions oi each plunger which are illustrated in those tigures ot the drawings which have. the corresponding numbers. For example, Fig. i2() illustrates the position of an)l plunger and its pressing mechanisms when approximately at the position izidiatcd on Fig. 19 b v the numeral 20. 'Thus it will be understood that thc movements of the plunger and pressing mechanisms are so related to each other that in the normal operation o1 the machine the plungcrs 121 are successively lowered into their respective molds in passing 'from the position 2() to the position 21 of Fig. 19, as illustrated in Figs, '.20 and 21, respectively; and cach of these normal plunger movements is followed up by the operation ot'ihe pressing mechanism at about the position illustrated in Fig. 22. straightening out the toggle joint and thus carrying the plunger to its lowest pressing position, or until disctmtinued by the releasing ot the magnet. illustrated at the leit hand side o't' Fig. 1` which normally takes place at about the rotary positionindieated by the numeral l in Fig. 1t). lilach succeeding plunger ai'ter being released from the magnet remains in its downward position oi Figs glass to ser, or until just. betere reaching the. position oi Fig. 19 at which position the plunger israised outl ot' the glass. returning gradually to the position of Fig. 20, to allow of the inverting ot' the pair of molds andthe feeding ot another charge oi glass to the. alternate mold.

The coupling engagement between any pressing lever and its` plunger mechanism is, however, conditioned upon two factors, first.

:2f-l and il long enouglrto allow theA the rotary position of the plunger mecha- 

